Living science. Naturalist Comics. Rem Word
iron filings burn in the air, whereas iron nails – except in pure oxygen… But the question is what happens when grinding a monolith or, conversely, sticking together dust again in the monolith with an absorption spectrum? Let us call for help the laws of quantum physics. In the monolith, the spectrum runs through all the energy levels, which – theoretically – as many as the atoms in the body. In a gas, individual atoms emit independently, only at several levels. But when neighboring atoms appear, the levels shift so as not to repeat each other, the prohibition principle introduced at the beginning of the 20th century works. Wolfgang Pauli: there can not be interconnected atoms, the energy parameters of which are completely the same. But the powder is an intermediate between gas and solid. Apparently, a sharp boundary, on which the properties vary in steps, cannot be drawn. And accordingly, the spectrum of the dust cloud, as the particles are crushed, will approach the spectrum of the gas. But what happens if you thicken it to the volume of the original monolith? When merging, for example, a hundred particles, each energy level will immediately take a hundred atoms. To restore order, adopted in the microcosm, each of these supersaturated levels will tend to split into a hundred isolated lines of the spectrum. The most natural way to restore the energy hierarchy for atoms of the newly formed monolith is to emit a certain number of electromagnetic quanta. Consequently, a condensed cloud of dust will become generally colder than the environment.
Are we, people, the same hubs? Than our cells are not isolated “specks of dust”, separated by membranes? But the permeability of membranes is constantly changing. And are not many properties of living organisms that are not amenable to modern science associated with the similar unification of many millions of “dust particles”?”
Continuation – in the article “Energy Hubs”, “TM” No. 6, 2002, already based on practical, not thought experiments. 1. cabinet with thermal insulation 2. Dewar vessels 3. continuous medium (water) 4. porous medium 5. electronic thermometers (error not more than 0.02 С) 6. temperature sensors. Two vessels – one with a porous medium, the other – with a solid, are located in a heat-insulated cabinet. The temperature of the internal environment is measured every 20 minutes using thermocouples. It turns out that the temperature in a tank with a granular medium (wet sand, etc.) changes abruptly. The continuous medium produces a flat temperature graph, without bursts and any periodicity. Porous, granular matter has the property to organize, that is, to collect energy in a certain space and time. It is probably its property that manifests itself at a different scale. Local heating occurs in a handful of sand, porous clay, one to two degrees, and over large areas. The temperature in such anomalies suddenly rises by tens, maybe hundreds of degrees. So the high level energy returns to the world. By ordering matter in a certain way, it is possible to achieve a predictable release of heat or cold in certain areas. Covered in feedback, the system creates a cold-warm pulsation. From this process you can get a steady flow of energy. The ordering can be done on the macroscopic (fractions of a millimeter) and micro levels (the distance between the atoms of the crystal). In the latter case, we seek “eternal sunshine.” In the first approximation, the system of concentration looks like the organization of flows of a homogeneous, initially separated substance to a certain common point, a kind of “heart”, followed by separation.
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